Structure-activity relationships: biological
13
Citation
128
Reference
10
Related Paper
Citation Trend
Keywords:
Lactam
Penicillin binding proteins
The major constituent of the bacterial cell wall, peptidoglycan, is comprised of repeating units of N-acetylglucosamine (NAG) and N-acetylmuramic acid (NAM) with an appended peptide. Penicillin-binding proteins (PBPs) are involved in the final stages of bacterial cell wall assembly. Two activities for PBPs are the cross-linking of the cell wall, carried out by dd-transpeptidases, and the dd-peptidase activity, that removes the terminal d-Ala residue from peptidoglycan. The dd-peptidase activity moderates the extent of the cell wall cross-linking. There exists a balance between the two activities that is critical for the well-being of bacterial cells. We have cloned and purified PBP5 of Escherichia coli. The membrane anchor of this protein was removed, and the enzyme was obtained as a soluble protein. Two fragments of the polymeric cell wall of Gram-negative bacteria (compounds 5 and 6) were synthesized. These molecules served as substrates for PBP5. The products of the reactions of PBP5 and compounds 5 and 6 were isolated and were shown to be d-Ala and the fragments of the substrates minus the terminal d-Ala. The kinetic parameters for these enzymic reactions were evaluated. PBP5 would appear to have the potential for turnover of as many as 1.4 million peptidoglycan strands within a single doubling time (i.e., generation) of E. coli.
Penicillin binding proteins
Residue (chemistry)
Gram-Negative Bacteria
Gram-Positive Bacteria
Cite
Citations (54)
Peptidoglycan is an unique composition of the real bacterial cell wall,because it plays a major role in the physiological functions of the bacterial cell wall and becomes the main subject of research on the bacterial cell wall at present.The chemical composition,structural feature,classification,separation and purification,biosynthesis,biological function,application prospect of peptidoglycan of the bacterial cell wall and so on are introduced.
Cell function
Cite
Citations (0)
Earlier studies have shown that the highly penicillin-resistant South African Strains of pneumococci contain altered penicillin-binding proteins (PBPs) (S. Zighelboim and A. Tomasz, Antimicrob. Agents Chemother. 17:434-442, 1980). We now describe a detailed quantitative characterization of the reaction of radioactively labeled penicillin with the PBPs of the penicillin-susceptible and penicillin-resistant pneumococci and several intermediate-resistance-level genetic transformants as well. The altered binding of the antibiotic by the PBPs of resistant cells appears to be due to a combination of two factors: lower drug affinity and change in the cellular amounts of PBPs. No alteration in the rates of deacylation of the penicilloyl-PBPs of the resistant cells was detected.
Penicillin binding proteins
Penicillin resistance
Cite
Citations (43)
We examined clinical isolates of Neisseria meningitidis relatively resistant to penicillin G (mean MIC, 0.3 micrograms/ml; range, 0.1 to 0.7 micrograms/ml), which were isolated from blood and cerebrospinal fluid for resistance mechanisms, by using susceptible isolates (mean MIC, less than or equal to 0.06 micrograms/ml) for comparison. The resistant strains did not produce detectable beta-lactamase activity, otherwise modify penicillin G, or bind less total penicillin. Penicillin-binding protein (PBP) 3 of the six resistant isolates tested uniformly bound less penicillin G in comparison to the same PBP of four susceptible isolates. Reflecting the reduced binding affinity of PBP 3 of the two resistant strains tested, the amount of 3H-labeled penicillin G required for half-maximal binding was increased in comparison with that of PBP 3 of the two susceptible isolates. We conclude that the mechanism of resistance in these meningococci relatively resistant to penicillin G was decreased affinity of PBP 3.
Penicillin binding proteins
Neisseriaceae
Neisseria
Penicillin resistance
Cite
Citations (87)
A large number of pneumococcal isolates (over 80 strains) from a variety of geographic locales and representing a spectrum of resistance levels from a penicillin MIC of 0.003 microgram/ml up to an MIC of 16 micrograms/ml were analyzed for their penicillin-binding protein (PBP) patterns. With a few exceptions, the great majority of strains with penicillin MICs up to about 0.05 microgram/ml contained the same set of five PBPs with molecular sizes typical of those of susceptible pneumococci. In strains with penicillin MICs of about 0.1 microgram/ml and up, virtually all isolates showed two common features: (i) all isolates showed loss of PBP 1A (98 kilodaltons) with or without a parallel appearance of a "new" PBP that ranged in molecular size between 96 and 97 kilodaltons; and (ii) in strains with penicillin MICs of 0.5 microgram/ml or more, PBP 2B could not be detected on the fluorograms even with very high concentrations of radioactive penicillin. Beyond these two common features, resistant strains with similar penicillin MICs showed a surprising variety of PBP profiles (i.e., in the number and molecular sizes of PBPs), each characteristic of a given isolate. We suggest that in pneumococci remodeling of critical PBPs in more than one way may result in comparable levels of penicillin resistance.
Penicillin binding proteins
Microgram
Penicillin resistance
Cite
Citations (96)
Abstract Wall chart : The predominant component of the bacterial cell wall, peptidoglycan, consists of long alternating stretches of aminosugar subunits interlinked in a large three‐dimensional network and is formed from precursors through several cytosolic and membrane‐bound steps. The high tolerance of the cell wall synthesis machinery allows for the use of labeled precursor derivatives to study diverse aspects of bacterial cell wall synthesis and interaction with antibiotics. magnified image Because of its importance for bacterial cell survival, the bacterial cell wall is an attractive target for new antibiotics in a time of great demand for new antibiotic compounds. Therefore, more knowledge about the diverse processes related to bacterial cell wall synthesis is needed. The cell wall is located on the exterior of the cell and consists mainly of peptidoglycan, a large macromolecule built up from a three‐dimensional network of aminosugar strands interlinked with peptide bridges. The subunits of peptidoglycan are synthesized inside the cell before they are transported to the exterior in order to be incorporated into the growing peptidoglycan. The high flexibility of the cell wall synthesis machinery towards unnatural derivatives of these subunits enables research on the bacterial cell wall using labeled compounds. This review highlights the high potential of labeled cell wall precursors in various areas of cell wall research. Labeled precursors can be used in investigating direct cell wall–antibiotic interactions and in cell wall synthesis and localization studies. Moreover, these compounds can provide a powerful tool in the elucidation of the cell wall proteome, the “ wallosome, ” and thus, might provide new targets for antibiotics.
Lysin
Cell envelope
Cite
Citations (34)
Resistance of S. pneumoniae to penicillin G and other useful antibiotics has sharply increase during the last years in many countries and especially in France. Resistance to penicillin G is due to an unpredictable qualitative and quantitative modification of several penicillin binding proteins. All the beta-lactams are affected but the level of cross-resistance depends upon the affinity of the beta-lactam for the modified penicillin binding proteins. As a consequence, the minimal inhibitory concentration of penicillin G and other useful beta-lactams have to be determined against S. pneumoniae isolated from serious infection, responsible for a clinical failure or resistant to penicillin G.
Penicillin binding proteins
Penicillin resistance
Pneumococcal infections
Cite
Citations (7)
Penicillin binding proteins
Penicillin resistance
Cite
Citations (26)
Since the discovery in 1965 that penicillin inhibits the transpeptidation reaction in peptidoglycan synthesis, a considerable effort has been put into the purification of enzymes that catalyse this reaction. This has resulted in the recognition that bacteria possess multiple forms of these penicillin-sensitive enzymes and has made it difficult to identify the precise target that penicillin inactivates to kill the organism. Recently penicillin-sensitive enzymes have been detected and studied as penicillin-binding proteins on sodium dodecyl sulphate polyacrylamide gels. The availability of this convenient method for identifying penicillin-sensitive enzymes has allowed biochemical and genetical approaches to be used to dissect their roles in the lethal effects of penicillin and other β-lactam antibiotics. Three penicillin-binding proteins (1B, 2 and 3) have been identified as killing targets for penicillin in Escherichia coli , whereas four other binding proteins are not implicated in the mechanism of action of the antibiotic. The complex biological effects that β-lactam antibiotics produce on the growth of E. coli can be explained by their interaction with the three killing targets. Progress in the correlation of penicillin-binding proteins with penicillin-sensitive enzymes and in the development of strains of E. coli that overproduce penicillin-binding proteins is discussed.
Penicillin binding proteins
Mechanism of Action
Cite
Citations (100)